Calculating machine



Nov. 7, 1939. E. c. MccLURE CALCULATING MACHINE Filed Sept. 2, 1936 9 Sheets-Sheet l E. C. MOCLURE CALCULATING MACHINE Nov. 7, 1939.

Filed Sept. 2, 1936 9 Sheets-Sheet 2 Nov. 7, 1939. a. c. M CLURE CALCULATING MACHINE Filed Sept. 2, 1936 9 Sheets-Sheet 3 ne/ 2 27770235 A/CZUQ Nov. 7, 1939. 5. c. MQCLURE 2,178,913

CALCULATING MACHINE Filed Sept. 2, 1956 9 Sheets-Sheet 4 Ewe/z .Ezvces Z 4/ 2 Nov. 7, 1939. E. c. MOCLURE 2.178.913

CALCULATING MACHINE Filed Sept. 2, 1936 9 Shuta-Sheet 5 Nov. 7, 1939. E. c. MccLuRE CALCULATING MACHINE Filed Sept. 2, 1936 9 Sheets-Sheet 6 Nov. 7, 1939- E. c. M CLURE 2,178,913

CALCULATING MACHINE Filed Sept. 2, 1936 9 Sheets-Sheet 7 Fig 50 v Z I Nova 7, 1939. (3, McCLURE 2,178.913

GALCULAT ENG MACHINE Filed Sept. 2, 1956 9 Sheets-Sheet 8 a A, F3. 7Z6 711; L

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NOV. 7, 1939 E; c. MccLuRE mucumwrm MACHINE Filed Sept. 2, 1956 9 Sheets-5heet 9 Patented Nov. 7, 1939 v UNiTeo STATE-S 2,178,913 CALCULATING MACHINE Ernest Charles McClure, Wahroonga, New South Wales, Australia, assignor to Powers Accounting Machines, Limited, London, England Application September 2, 1936, Serial No. 99,155 In Great Britain September 5, 1935 4 Claims.

This invention relates to machines for multiplying two factors and has for its object to provide amechanism for accumulating the different components of the partial products obtained from such a multiplication.

According to the invention mechanism for accumulating the partial products obtained from the multiplication of two factors comprises in combination a frame, a plurality of accumulator plates pertaining to a single denomination of the product, said plates being slidably mounted in said frame, a settable stop for one of said plates, said stop beingmounted on the frame, a settable stop for the adjacent plate, said second mentioned stop being carried on said first mentioned plate, means for setting said stops and means for maintaining the stop which is carried on said first mentioned plate in operative relation with the setting means irrespective of the position of the plate on which said stop is carried.

In order to render the invention clear one construction according thereto will now be described as applied to a sterling multiplying machine as described in British patent specification No. 440,180, (corresponding to United States Patent No. 2,113,352, dated April 5, 1938,) with reference to the accompanying drawings in which:

Fig. 1 illustrates the mechanism in outside elevation with one side plate of the frame removed;

Figs. 2, 2a, 2b, 20 together show diagrammatically the arrangement of the plates of the mechanism according to'the invention which receives the different components of the partial products;

Fig. 3 is a side elevation with the lowest de= nominational plate removed;

Fig. 4 is a' view showing the tens of shillings final product plate and associated mechanism for transferring one or more units to the units of pounds denomination;

Fig.5 is a plan of themechanism of the invention;

Figs. 6, 7 and 8 show the mechanism for con trolling a register to which the final products are transferred;

Fig. 9 shows mechanism for controlling the final product plate of the units of pounds denomination; and

Fig. 10 shows the construction of the restoring bar for returning all the plates to their normal position. I I

In order to facilitate understanding of the invention those parts of the machine which also appear in British patent specification No. 440,180 will be referred to in this specification by the same reference numerals as those which they bear in British specification No. 440,180.

In the construction shown in the drawings the denominational pairs of quadrantal racks I50 and I5I described in British specification No. 440,180 are replaced by denominational pairs of arms 600 which are pivoted on the shaft 212 and to which are pivoted at 314 the connecting plates I46 and, I41, each of which has a slot I49, 9a in which rides a pin I52.

As described in British patent specification No. 440,180 the pins I52 also slide in slots I, Illa formed in radial arms HI, I42- of bell crank levers which are set from the multiplier keys 64. a

When the pins I52 have been positioned by the keys 64 as described in British patent specification No. 440,180 the arms 6000f all the denominations are released to the action of springs 201 and swing clockwise until their pins I52 reach the bottoms of the slots in the respective partial product plates II5, II5a, IIB, Ga and so on.

As explained in British patent specification No. 440,180 these partial product plates are disposed in pairs, one pair for each sterling denomination.

In each pair one plate, e. g., I I5, gives the component in the denomination concerned of a multiple of a multiplicand digit in the same denomination while the other plate, e. g., II5a, gives the component in the next higher denomination of the same multiple.

Thus after the pins I52 have reached the bottom of the slots presented to them by the corresponding partial product plates the corresponding arms 600 will be positioned to represent different components of the final product.

The object of the present invention is to provide a mechanism for adding these components together to give the final product.

In the machine described in British patent specification No. 440,180 the pins I52 were normally disposed just clear of the peripheries of their respective partial product plates II5, HM and so on, so that when one of the partial product plates was set torepresent zero the corresponding pin I52 did not move at all.

When the mechanism according to the present invention is applied to the machine described in British patent specification No. 440,180 however, certain of the pins I52 are normally disposed at a distance from the periphery of their respective partial product plates such that when the said partial product plates are set to represent zero, the corresponding pins I52 move to an extent representing one unit before being arrested by engaging the periphery of the plates.

The purpose of this one unit extra movement will be explained later.

The mechanism of the invention comprises a series of sliding plates Bill to GM mounted in a frame SIG which is attached to the side plates of the machine described in British patent specification No. 440,180.

Mounted to slide vertically in comb bars of which the ends are carried by the side plates of the frame BIB is a series of vertical rods 8I8 to 628, one for each of the arms 600. Each rod i I I- I 6|8 to 628 is pulled down by a spring and is lifted under the control of the corresponding arm 60!! by the following mechanism (see Fig. 1).

The upper end of each arm 600 is pivoted at 638 to one arm of a bell crank 63! freely pivoted on a rod 632 mounted transversely between the side plates of frame BIS.

The lower ends of the rods SIB, SIS, GZI, 623, 626 and 62! (Figs. 2, 2a, 2b and 2c) rest on the upper ends of rods 635 pivoted to their corresponding bell cranks, as shown for the rod I! in Fig. 1. The rods 620, 622, 624, 625 and 628 however are displaced from the other rods, and the lower end of each of these rods rests on a lateral extension 631 of the corresponding vertical slide 635 which has its lower end pivoted to the corresponding bell crank 63!.

Thus when an arm 600 moves clockwise and is positioned by its corresponding pin I52 coming to 20 rest on a step of the corresponding partial product plate H5, etc., the corresponding rod 618 to 628 will be raised to an extent representing the digit represented by the movement of the corresponding arm 600. a

The action of the rods 618 to 628, which ihay conveniently be termed setting rods, is best explained by reference to the rod 618 and the plate 6M shown in Fig. 1 which handle the Mad. component of a multiple of eighths of a penny.

The plate GUI has a series of steps 638 formed therein and the rod H8 carries aprojection Glfla which is normally in a position such that it is engaged by the vertical face of the lowermost of the steps 638 as shown in Fig, 1.

If the pin I52 which co-operates with the partial product plate lli (which is stepped to represent V d. components of multiples of eighths of a penny) moves to an extent representing 3 digits then the corresponding arm 600 will move to an extent representing 4 digits and the projection 6l8a will be positioned so that when the plate 60! moves to the right in the manner explained later, the vertical face of the fourth step 638 from the bottom will engage the projection 618a and arrest the plate 6M after a movement representing 4 digits.

In order to explain the manner in which all the plates 60! to GM co-operate reference will now be made to Figs. 2, 2a, 2b and 20 which show these plates and their associated parts diagrammatically in perspective, and the operations involved in accumulating the partial products obtained from the multiplication of the amount 24:15:10%d. by '7 will be described. Since the machine is arranged to operate in eighths of a penny, the amount of %d. included in the above multiplicand 24-:15:10%d. will be dealt with as 6/8d., i. e. 6 digits in the eighths of a penny denomination.

The partial products obtained from this multiplication are as follows:

Bhill Shhlll' P yd ngs gs ence 100 mm tens units I. $ZOX7 1 4 of the two components is greater than the maximum number of units in that denomination so that one unit has to be transferred to the higher denomination.

In the mechanism according to the invention, as will now be explained with reference to Figs. 2, 2a, 2b and 2c means is provided for effecting these transfers from one denomination to a higher denomination when necessary.

Referring now to Figs. 2, 2a, 2b and 2c and assuming that the partial product plates H5, 5a and so on have been set to represent the partial products of the multiplication of 24:15:l0 7 then the different arms 500 of which there is one for each partial product plate, will move clockwise to extents representing the various partial products set out above but certain of arms 6" as will be explained more fully hereinafter commencing with the arm corresponding to the partial product plate H5 will move one additional unit as well.

The arms 600 having all been positioned by the entry of their corresponding pins I52 into the notches in the partial product plates which have been presented to them, the arm 600 for the eighths of a penny component of a multiple of eighths of a penny will have moved clockwise to an extent representing 2+l=3 digits and therefore the corresponding setting rods 6|! will have arisen to an extent equal to the height of three of the steps 638 in the plate 6M.

The height of the steps 638 equals the width of these steps, so that when the plate GUI moves rearwardly under the action of a spring sum, as

' described later, the vertical face of the third step from the bottom will engage the projection Blla on the rod 618 and will arrest the plate 60!.

It is required to transfer this amount of 2 eighths of a penny to the eighths of a penny denominational wheel of a final product register and to this end, an actuator rack M9 for this wheel is provided which is set from the plate BM in the following manner:

The plate 60! is provided with a second series of steps 68!! and co-operating with these steps is a projection 649a on the rack 649. This projection 649a isnormally at the top of a slot 860a formed in the plate 60! adjacent the steps $60 and of a depth such that the bottom of the slot 660a is level with the bottom of the lowermost of the steps 660. The purpose of this slot is to permit lowering of the rack 649 in order to clear the register, and the operation of clearing the register will be described later.

The highest of the steps 660 is the No. 0 step, the next lower step is the No. 1 step, the third step is the No. 2 step and so on.

As described above the plate GUI has been arrested by the third step 638 from the bottom engaging the projection 618a on the setting rod H8, and this position of the plate GUI brings the third step 860 from the right directly below the projection 649a on the actuator rack 649.

The rack 649 is then lowered by mechanism which will be described later and is arrested by its projection 649a engaging with the third step 660 from the right. This is the No. 2 step and accordingly the position of the actuator 9 represents 2 digits, i. e., 2 eighths of one penny.

It will be noted that the projection 9a is normally one step to the right of the No. 0 step 649a. It is for this reason that the corresponding 7 arrests 3 arm set is permitted to move to an extent representing the actual digit involved plus one unit.

In the foregoing example theplate 6M moved 3 steps but the actuator 6 359 has been set to repre= 55 sent 2 eighths oi one penny. 7

After the actuator 549 has thus been set, the corresponding register wheel is moved into engagernent with the. teeth on said actuator and the latter is returned to normal position, whereby the 10 amount of o 2 /8d. is transferred to the register wheel in theeighthsof a penny denomination.

As already shown the pence component of the product of %d.(6/8d.) is 5d, and consequently the arm 506 for the pence component of a multiple of eighths of a penny will have moved clockwise to the extent of 5 units and accordingly the corresponding setting rodfiit will have arisen to an extent equal to the height of five oi the steps 639 in the corresponding plate 602. 7

2o Since this plate only handles the pence components of multiples of eighths of a penny,

and not the pence digit oithefinal product, the

plate 602 is not provided with steps such as the steps Emil in the plate Edi, or with an actuator rack for operating a registerwheel.

The plate E592 merely serves to transfer to the next plate 603 the pence component 5 of the product of the amount %d.(6/3d.)x7.

This plate 603 receives the pence component of the pence digit of the multiplicand multiplied by "l and also the pence component of the eighths of a penny multiple fromthe plate 602.

Tothis end the settingrod 820 for the plate 603 ismounted to slide vertically on the plate 592 by. means of pins andslotstzlib so that when the plate 602 moves to the right,the setting rod 52$ for the platetllii moves with it and the plate 603 also to the same extentifl,

Itwill beobserved that although the rod Mil it 4, moves laterally with the plate M2 the corresponding armfillt can still transmit vertical movement to the rod 62h slnce asthe latter moves with the plate 662 it slides along t'he lateral extension 631 oi the corresponding vertical slide 6355. I

- 4 As stated above the vertical rod 6l9 has moved up to the extent of 5 steps 6 39 and therefore the plate 583 will move 5 steps to the right before it is arrested by the projection 6i9a on rod file, carrying with it also the rod 620 which through its 5 projection Biflocarries the plate 603 also 6 steps to the right The pence component of the pence digit (10d) of the multiplicand multiplied by 7 is -l0d.(10d.. '7, =70d.=5 sh. 10d.).

Therefore the arm 698 corresponding to the partial product plate H5 will move clockwise to 4 the extent of l0+1=i1 units and the correspondingsetting rod 628 will move 111 ,11 steps until its H projection 626a is opposite to the eleventh step so from thebottom of a series of steps 64%] formed in the plate Silt.

, The plate tilt will therefore move to the right I a further eleven steps but since the plate 6% has already moved five steps simultaneously with the 65 plate $62, the total movement of plate 603 is iovement of 16 steps actually represents '15 p since one step movement is required to bring Midi step of the steps 636i below the projection 6553a on the corresponding actuator 650. But I l5d.=lsh. 3d, and therefore it is necessary to set the actuator see to represent 3d. and to carry 1 unit to the units of shillings denomination.

The maximum possible amount of pence which can be received by the plate 683 is 11d. through the setting rod 620 and 7d. through the plate 502,

1d. being the maximum possible pence component of any multiple of eighths of a penny (%d. 9=7%d.). Therefore the maximum movement of plate 603 is 11+7+l=19 steps, which i would represent 18d.=l sh. 6d.

In order to transfer the pence digit of the final product to the corresponding register wheel, two series of steps indicated at GBI are provided in the plate 593 for co-operation with the projection 6500 on the corresponding actuator 650.

In the first series there are twelve steps representing 0, l, 2, 3, 4, 5, 6, 7, 8, 9, 10 and 11 pence respectively and in the second series there are seven steps representing 0, l, 2, 3, 4, 5 and 6 pence respectively.

In the present example the plate 603 has moved 16 steps and therefore the fourth step in the second series of steps I representing 3d. will be brought below the projection 650a on the actuator 650, which will consequently be set to 3d.

In order to transfer the required one unit to the shillings denomination the plate 603 is provided with a slot 65'! of the form shown with which engages a pin 668 on an arm 669 secured to a sleeve 61! rotatably mounted on a shaft 610 secured to the frame H5.

In the plan view (Fig. 5) the arm 669 is shown to the left of plate 603 but in the perspective view shown in Figs. 2, 2a the arm 663 is shown to the right of the plate 603 for the sake of clearness.

The slot 66'! is formed with a cam portion 661a so located that if the plate 603 moves to the right more than 12 steps, 1. e., registers more than 11d.,

then the pin 66B rides up the cam 661a against the action of a spring 6690 and rocks the sleeve EN.

The rocking of the sleeve 61! transfers 1 shilling to the units of shillings denomination by means of mechanism which will be described later.

In the aforementioned example of the multiplication of 24:15:10 'I the arm 600 for the units of shillings component of the pence multiple will have moved clockwise to the extent of 5+1 units=6 units and therefore the corresponding setting rod 62!! will have risen six steps to bring its projection SZIa into line with the 6th step from the bottom of a series of steps t ll formed in the plate 604 which receives the units of shillings component of a multiple of pence. When this plate 504 moves to the right it will therefore be arrested after a movement equal to the width of six of the steps 6H.

In order to handle the units of shillings component of any multiple of a units 01 shillings digit of a multiplicand a plate 605 is provided, of which the operation is as follows:

The units of shillings component of the pence multiple and the units of shillings component of the units of shillings multiple have to be added together to give the units of shillings digit of the ings component of multiples of units of shillings.

This rod 622 is mounted on the plate 604 by means of slots 6221) engaging pins projecting from the plate 604. The rod 622 carries a projectlon 622a engaging in a series of steps 642 formed in the plate 605 referred to above so that when the plate 604 moves to the right six steps the plate 605 also moves to the right six steps.

Since, however, the units of shillings component of the product of the units of shillings digit x7 is 5, accordingly the corresponding arm 600 will have moved forward 6 steps and will have lifted the setting rod 622 for the plate 605 to the extent of 5 steps. In this connection it should be noted that the three plates 604, 605

and 606 together serve to set a single actuator rack 65l which takes its setting from the plate of the plates 604, 605 or 606 to make theone extra step movement necessary to bring the plate 606 from the position in which the slot 6620 is below the projection 65la to the position in which the nought step 662 is below this projection 65la. Since the plate 604 has made this one extra step movement it is not necessary for the plate 605 or for the plate 606 to move an extra step,

Therefore, as explained above, the setting rod 622 for the plate 605 rises only five steps and therefore when the plate 605 moves to the right it will move until the fifth step 642 engages the projection 622a on the rod 622 whereby the plate 605 will have moved five steps to the right in respect to the plate 604. But the plate 604 has already moved six steps to the right so that the total movement of the plate 605 is eleven steps to the right.

Mounted to slide vertically on the plate 605 is a slide 613. This slide is provided with slots 614 engaging with pins carried by the plate 605 and engaging in a slot 615 formed in the slide 613 is a pin 612a carried on an arm 612 secured to the sleeve 6".

It will be remembered that in the case of the pence plate 603 this plate had moved to an ex tent greater than 11d. and accordingly the pin 668 on the arm 669 secured to the other end of the sleeve 61! has ridden up the cam surface 661a of the slot 661 thereby rocking the sleeve 61L This rocking movement of the sleeve 61! lifts the arm 612 secured thereto and through the pin 612a on the end thereof lifts the slide 613.

Secured to the slide 613 is a lateral projection 6130 which normally engages with the vertical surface of a step 655 formed in the units of shillings product plate 606. When the slide 613 is lifted the projection 613a moves upwards to the extent of the height of the step 655 and permits the plate 606 to move one step to the right, as will readily be seen from the drawings.

As already mentioned the plate 605 has moved to the right to the extent of eleven steps and has therefore carried with it the slide 613 and therefore also the plate 606 which is connected to the slide 613 by the projection 613a. In addition however, the slide 613 has been raised one step by the rocking of the sleeve 61! and consequently the plate 606 has moved one step further to the right, making twelve steps in all.

In this connection it will be noticed that the slot 615 in the slide 613 is of suflicient length to permit the pin 612a to remain in engagement therewith throughout the maximum possible travel of the plate 605.

The amount represented by this twelve step movement of the plate 606 has now to be transferred to the units of shillings wheel of the final product register and to this end the plate 606 11y be set to 1, shilling.

' term the pence plate 603.

is provided with two series of ten steps 662 with which co-operate a projection 65la on the actuator rack 65l for the units of shillings register wheel. The projection 65la is normally over the deep slot 662a in the plate 606 and therefore of the twelve steps movement the first step is merely for the purpose of bringing the projection 65ia over the nought step in the plate 606. Consequently the actual movement of the plate 606 is. only. representative of-eleven shillings.

This amount of eleven shillings is made .up of one unitlintheshillingsdenomination and one unit'in the tens of shillings denomination and 606 and therefore it is only necessary for one therefore the twelve steps movement of the plate 606must'set the actuator 65] to represent one the plate 606 has moved 12 steps the second step in the secondseries of steps 662 representing 1 shillingf will' be broughtbelow the projection 65la on the actuator 65i which will consequent- In order to transfer the required 1 unit to the tens of shillings denomination the plate 606 is provided with a slot 616 similar to the slot With this slot 616 engages a pin 611 carried on an arm 618 secured to a sleeve 619 freely mounted on the shaft 610 (Fig. 5). The slot 616 is formed with a cam portion 616a so located that if the plate 606 moves to the right more than steps,'i. e., registers more than 9 shillings, then the pin 611 rides up the cam 616a against the action of a spring 618a and rocks the sleeve 619. The rocking of the'sleeve 619 transfers one unit to the tens of shillings denomination by means of mechanism similar to that already described in connection' with the transfer of l shilling from the pence to the units of shililngs denomination.

Considering now the tens of shillings denomination. The tens of shillings digit in the final product is made up of two components, namely the tens of shillings component of the units of shillings multiple and the tens of shillings component of the tens of shillings multiple. In the present example the tens of shillings component of the units of shillings multiple is 3 (5 sh. 7=35 sh.) while the tens of shillings component of then tens of shillings multiple is 1 (10 sh. 7= 3.10.0.).

Accordingly the arm 600 associated with the partial product plate 1a which carries steps representing tens of shillings components of a shillings multiple will move clockwise 3+1 steps. Consequently the corresponding setting rod 623 will have risen to an extent equal to the height of 4 of the steps 643 in the corresponding plate 601. The adjacent plate 600 receives the tens of shillings component of the tens of shillings digit of the multiplicand multiplied by 7 and also the tens of shilings component of the units of shillings digit of the multiplicand multiplied by '7. Therefore the setting rod 624 for the plate 606 is mounted to slide vertically on the plate 601 by means of pins and slots 6242; so that when the plate 601 moves to the right the setting rod 624 for the plate 606 moves with it and the plate 608 also to the same extent.

As stated above the setting rod 623 has moved up to the extent of 4 steps 6 and therefore the plate 601 will move 4 steps to the right before it is arrested by the projection 623a on rod 623 carrying with it also the setting rod 624 which through its projection 624a carries the adjoining plate 660 also 4 steps to the right.

The tens of shillings component of the tens of shillings digit 1 of the multiplicand multiplied by '7 is 1 (10 sh. '7=3.10.0.). Therefore the arm 600 corresponding to the partial product plate I I8 will move clockwise to the extent of 1 unit since the additional unit of movement required to bring the final product plate 609 for the tens of shillings denomination to the zero position has already been made by the plate 601. Accordingly the corresponding setting rod 624 will move up one step from the bottom of the series of steps 644 in the plate 608 and therefore the plate 608 will be permitted to move one step to the right relatively to the plate 601. Since the plate Bill, however, has already moved 4 steps to the right the total movement of the plate 608 is 5 steps to the right.

It will be remembered however that the units of shillings final product plate 606 moved to an extent greater than 9 shillings and that therefore one unit has to be carried to the tens of shillings denomination and that this movement of the units of shillings plate 606 caused the sleeve 679 to rock.

This rocking movement of the sleeve tilt effects the transfer of one unit to the tens of shillings denomination by the following means:

Secured to the sleeve 6'19 is an arm 680 carry-- ing a pin 68! engaging in a slot 682 formed in a slide 683 which is mounted to slide vertically on the plate 608 by means of pins and slots 684. This slide 683 carries a projection 683a engaging with a step 656 formed in the plate 609.

When the plate 608, as described above, moved through 5 steps plate 609 also moved through 5 steps together with it by virtue of the connection between plates 608 and 609 constituted by the projection 683a. The rocking of the sleeve 619 however raised the arm 68!] and therefore the slide 683 so that the projection 683a was lifted to the extent of one step 656 thereby permitting the final product plate 609 to move one extra step, making six steps n all.

In order to transfer the tens of shillings digit of the final product to the corresponding register wheel a series of steps 683 is formed in the plate 609 for co-operation with a projection 652a on a corresponding actuator 652.

In the tens of shillings denomination only 1 or can be registered and therefore the steps 663 are made to represent 0 and l alternately, there being provided the slot 663a adjacent the 0 step, with which slot the projection 852a is normally in register.

It will be understood that the maximum amount which the tens of shillings plate 609 can receive from the shillings denomination is 8 digits.

These 8 digits however, which represent 80 shil-- Pings, equal 4.00. therefore provision must be made for carrying 4 digits to the units of pounds denomination when required. In addition, when the tens of shillings digit is an odd number not only must a carry be effected to the units of pounds but also the tens of shillings denomination must register 1, for example 30 shillings: 1.l0.0. 50 shillings:2.l0.0. and so on. Accordingly the steps 663 are arranged in the following manner: 0, 1, 0, 1, 0, l, 0, l, 0, l and a further series of steps 65? is provided in the plate 609 with which engages a lug 685 carried on an arm 686 secured to a sleeve 687 rotatably mount- (d on the shaft 610 arm 686 is pulled upwardly by a spring which is not shown. When plate 609 moves until the lug 685 leaves one of the steps 651 and moves into engagement with the next, then the consequent rocking 'of sleeve 681 carries one unit to the units of pounds denomination.

Although each of the steps 65'! is of the same height as that of the steps 644 each of the steps 651, with the exception of the lowermost. is double the width of a step 663 and the lowermost step 65'! is three times the width of a step 663.

If the plate 609 is set so that the projection 652a is over the first or second of the steps 863 from the right then this indicates a value of 0 or 10 shillings and no carry to the units of pounds is necessary. Therefore the lowermost of the steps 85'! must be of a width at least equal to twice the width of a step 663. Since, however, the plate 609 moves one step before the first of the steps 663 comes below the projection 652a the lowermost step 651 is made three times the width of one step 663.

If, however, the plate 609 moves until the projection 652a is over the third or fourth step 663 this indicates a product of 20 shillings or 30 shillings in both of which cases a carry over of one unit is required to the units of pounds denomination, therefore the second step 651 is made twice the width of one step 663 and likewise with all the other steps 651.

In the present example, as explained above, the tens of shillings plate 609 has moved six steps'which will bring the sixth step 663 below the projection 652a on the tens of shillings actuator rack 652. Accordingly this rack will be set at 1, i. e., 10 shillings. At the same time the six steps movement of the plate 609 will have brought the lug 685 on arm 686 into engagement with'the third step 651 from the bottom whereby the sleeve 681 will be rocked to transfer 2 to the units of pounds denomination by means of the mechanism which will be explained later.

In the aforementioned example of the multiplication of 24.15.10% by '7 the units of pounds component of the product of the tens of shillings digit is 3 (l0 sh. 7=3.10.0). Consequently the arm 600 for the units of pounds component of the tens of shillings multiple will have moved clockwise to the extent of 3+1 units=4 units and the corresponding setting rod 625 will there-"a fore have risen four steps to bring its projection 625a into line with the fourth step from the bottom of a series of steps 645 formed in the plate Bill which receives the units of pounds component of a multiple of 10 shillings. When this plate BIO moves to the right it will therefore be arrested after a movement equal to the width of four of the steps 645.

In order to handle the units of pounds component of any multiple of a units of pounds digit of a multiplicand a plate 6| l is provided of which the operation is as follows:

In the example now being dealt. with the units of pounds component of the units of pounds digit 4 is 8 (4 7=28).

The units of pounds component of the tens of shillings multiple and the units of pounds component of the units of pounds multiple have to be added together to give the units of pounds digit of the final product but, as in the present case,

the tens of shillings final product plate 609 moved to an extent representing 2.l0.0, a further 2 has to be added in the units of pounds denomination. As already mentioned this carry-over of 2 is effected by means of the sleeve 68'! while the units of pounds component of the tens of shillings multiple is received by the plate 610 and the unit of pounds component of the units of pounds multiple is received by the plate 6| l.

As explained above the plate 6!0 for the units of pounds component of the tens of shillings multiple will, ini-ighe present example, move four steps to the rightf Mounted to slide vertically on this plate 6!0 is the setting rod 626 for the units of pounds component of multiples of units of pounds. This rod 626 is mounted on the plate 6!0 by means of slots 626b engaging pins projecting imp: the plate 6!0. The rod 626 carries the projection 626a engaging in a series of steps 646 formed in the plate 6!! referred to above so that when the plate 6!0 moves to the right four steps the plate 6!! also moves to the right four steps.

Since however the units of pounds component of the product of the units of pounds digit 4 multiplied by 7 is, as stated above, 8 accordingly the corresponding arm 600 will have moved forward 8 steps and will have lifted the setting rod 626 for the plate 6!! to the extent of 8 steps and therefore when the plate 6!! moves to the right it will move until the eighth step 646 engages the projection 626a on the rod 626 whereby the plate 6!! will have moved-eight steps to the right relatively to the plate 6!0. But the plate 6!0 has already moved four steps to the right so that the total movement of the plate 6!! is twelve steps to the right.

Mounted to slide vertically on the plate 6! I is a slide 688. This slide is provided with slots 689 engaging with pins carried by the plate 6| I, and engaging in a slot 690 formed in the slide 668 is a pin 69! carried on an arm 692 secured to the sleeve 681.

It will be remembered that in the case of the tens of shillings plate 609 this plate had moved to an extent which caused the lug 685 on the arm 686 to rise in engagement with the third step 651 in the plate 609. This rocking of the sleeve 68! lifts the slide 668 through the action of the pin 69! to an extent suflicient to carry 2 to the units of pounds final product plate 6l2.

In order to permit this movement of the plate 6! 2 relatively to the plate 6!! the plate 6!2 is provided with a cam slot 693a engaging with a pin 693 projecting from the slide 686 so that when the slide 688 is raised by the rocking of the sleeve 68! the action of the pin 693 on the slot 693a moves the plate 6!2 to the right relatively to the plate 6!! by a number of steps dependent upon the particular step 651 with which the lug 685 is engaged.

As already mentioned the plate 6!! has already moved to the right to the extent of twelve steps and has therefore carried with it the slide 688 and therefore alsothe plate 6I2 which is connected to the slide 688 by the pin 693. In addition however the slide 688 has been raised two steps by the rocking of the sleeve 68! and consequently the plate 6!2 has moved two steps further to the right making fourteen steps in all.

The amount represented by this fourteen step movement of the plate 6!2 has now to be transferred to the units of pounds wheel of the final product register and to this end the plate H2 is provided with the steps 664 arranged in two series, these steps co-operating with the projection 653a on the actuator rack 653 in the units of pounds register wheel.

In the present example the plate 6 I 2 has moved fourteen steps and therefore the fourth step in the second series of steps 664 representing 3 will be brought below the projection 653a on the actuator 653 which will consequently be set to 3.

In order to transfer the required one unit to the tens of pounds denomination the plate H2 is provided with a slot 694 similar to the slot 661 in the pence plate 603, with which co-operates a pin 695 and a sleeve 69'! to transfer one unit to the tens of pounds denomination in a manner similar to that for the transfer of one shilling from the pence to the units of shillings denomination.

The plates which receive the tens of pounds components of the units of pounds multiple and of the tens of pounds multiple are respectively shown at (H3 and (H4 in Figs. 2b and 2c and the setting rods for these plates are shown at 62! and 628 while the mechanism for transferring one unit from the units of pounds to the tens of pounds denomination is shown at 691 to 102 in Figs. 2b and 2c. The tens of pounds final product plate 6l5 (Fig. 5) however is not shown, but from the foregoing description of the action of the mechanism in other denominations the operations involved in the tens of pounds denomination will be clear, as well as theaaperations in higher denominations; in each of which there are three plates of which two are similar to the plates 6 l3 and GM while the third is similar to the plate 6!5, which in turn is similar to the plate 6l2.

With regard to the precise number of steps in the various sets of steps in the plates which have just been described it is pointed out that for manufacturing reasons as many of the plates as possible will be made identical and where complete identity between the plates is not possible identity between the corresponding sets of steps will be preserved as far as possible. Hence the number of steps in the sets of steps 638, 639, 640, 64!, 642, 643, 644, 645, 646, 641 and 648 is made equal to the maximum possible number of steps necessary in any one of these plates.

Similarly in the plates 603. 606, BIZ and 6l5 the two series of steps in each plate, namely, 66!, 662, 664 and 665 are each provided with ten steps although all of these steps in the second series in each set may not be required.

In order to actuate the arms 600 a cam 363 secured to the main shaft 232 is provided for each arm all these cams being disposed to actuate all the arms 600 simultaneously. The cams 362 described in British patent specification No. 440,180 are omitted in the present construction.

The final product plate in each denomination, e. g., plates 66!, 603, 606, 609, M2 are all pro vided with springs 60! (1, 603a, and so on tending to pull them to the right whereby the other plates are also pulled to the right owing to the connection between these plates and the plates 60!, 603 and so on associated with them. For example, spring 60911 for plate 609 will pull plates 608 and 60'! also. The plates are prevented from so moving by a restoring bar 105 carried between two arms 10'! (of which only one is shown). These arms are pivoted on the shaft !25 and are extended below this shaft for actuation by a cam 108.

All the denominational actuator racks 649 to 653 are pulled downwardly by springs onto a bail 109 which normally maintains them in their highest position. The bail E69 is carried between two arms H pivoted to the side plates of the frame at 1!! and connected by links iii? to two bell cranks H3 pivoted on a shaft H4, and each engaging a cam H (of which one only is shown) secured to the main shaft 232.

When the main shaft 232 rocks, the bail 109 descends and permits the actuator racks 649 to 653 as well as the racks of higher denomination to descend also under the action of their springs whereby these racks take up positions depending upon the particular step in the final result plates tilt, tilt, tat, @til, ti? and so on with which the corresponding projections (ilila to 653a engage.

After the actuator racks E li? to have been thus set the register wheels are brought into engagement therewith and the shaft 232 then rocks back again whereupon the cam liEi returns the bail 709 to its uppermost position thereby restoring the actuators t lil to 53 to their zero position. This return movement of the actuators transfers to the register wheels the amount to which the actuators have been set.

The register wheels indicated at lit in Fig. 6 are carried on a shaft i ll which is slidable longitudinally in the side plates of the machine frame, the shaft being pressed by means of a spring not shown against a cam lit carried on the upper end of a vertical rod M9.

The register wheels M6 are normally disposed to one side of their respective actuators 63% to (352 so that the teeth of the register wheels are out of engagement with the teeth of the actuators. In order to bring the register wheels into engagement with the actuators the rod M3 is pulled downwardly whereupon the cam lit displaces the register shaft ill longitudinally until the register wheels llii engage with the actuator racks.

In order to operate the rod Mil a pair of cams 72d. J20 is provided on the main shaft These cams have the same contour but are reversed relatively to one another and means is provided for bringing the rod HQ into operative relationship with the cam lii'tlwhen the shaft 232 rocks in one direction and into operative relationship with the cam llfil when the shaft rocks back again.

It will be understood that the provision of two cams 712d, lill is required in view of. the fact that in the machine described in British patent speci iication No. 449,18ii to which the present invention is applied, operation of the machine is ef" fected by pulling the operating handle forwardly and allowing it to return under the action of a spring so that the movement of the main shaft 232 is a rocking movement and the shaft there fore does not make a complete revolution.

In order to operate the rod lit from the two cams llfit, il2l'two fingers U22, U23 are pivoted to the lower end of the shaft M9. Each of these fingers has a lug 72 at its lower end and in the normal condition of the machine the lug 12d lies under one end of a lever H26 pivoted at 17271 on a shaft carried in the side plates of the frame and having pivoted to its other end a depending lug (1223. Also pivoted on the shaft 712? is a similar lever 7129 having a lug "Mill. The depending finger E23 however is normally in a position such that its lug 325 is clear of the lever T29.

In order to maintain the two fingers i122, H23 in their relative positions each is connected'by means of a link ltll, 7132 respectively to opposite ends of a lever 733 secured to a shaft 13% to which is also secured an arm T35 pivoted to the link 33 3 shown in Figure ill of British patent specification No. 443,180; As described in this prior British specification this link 3236 is moved to the right by depression of the clearance key 635.

When the clearance key is not depressed the lever i333 and associated parts are in the position shown in Fig. 6 and consequently the finger E22 is disposed in vertical alignment with the rod H3 so that its lug 124 is beneath the lever I26. The lug 128 of this lever I26 engages with the cam so that with this position of the parts, when the handle of the machine is pulled forwardly and the shaft 232 rocks in an anticlockwise direction the vertical portion 12Ga of cam E20 strikes the depending lug 128 of lever 126 and swings this lug to one side without lifting it; therefore on the forward stroke of the operating handle the wheels H6 remain out of engagement with the actuators.

On the return stroke of the operating handle however, the shaft 232 rocks in a clockwise direction and as the cam 120 returns its inclined face 12Gb engages-with the lug 128. This engagement of the cam 120 with the lug I28 tends to swing the latter counterclockwise about its pivot but such movement is prevented by a projection 126a on the lever 126 which acts as an abutment for the lug 128 so that the cam 12!! lifts the lug I28 thereby rocking the level 126 which by engaging the lug 124 pulls down the rod H9 whereby the register wheels H5 are moved into engagement with the actuators 149 to 152.

This action of course takes place after the actuators have been set and the cam 120 has a contour of suflicierit length to maintain the wheels H5 in engagement with the actuators while the latter are being restored to zero by the lifting of the restoring bail 109.

After the actuators M9 to 152 and so on have been restored thereby transferring to the register wheels H5 the amount to which the actuators were set the cam 120 leaves the lug 128 whereupon the spring 1 I911 lifts the rod H9 thereby returning the wheels H5 laterally to the disengaged position.

After this operation, cam 108 returns the stepped plates Bill to GM, etc., to the left to their normal position. The machine is now at rest with all its parts in their normal position with the exception of the register wheels which hold the product of the calculation made. In order to clear the register wheels in readiness for another calculation the clearance key 435 described in British patent specification No. 440,180 is depressed and then the operating handle of the machine is pulled forwardly and allowed to return by means of its spring.

Depression of the clearance key 435 pushes the link 384 to the right and thereby rocks the lever 133 in a counterclockwise direction. This movement of the lever I33 swings the finger 122 counterclockwise so that its lug 124 is out of the path of the lever I26 and simultaneously swings the finger I23 clockwise so as to bring its lug below the lever I29.

As the shaft 232 now rocks counterclockwise the inclined portion 12H) of the cam 'l2l strikes the depending lug I30 and tends to rock this lug in a clockwise direction. This lug however carries a projection 136 which engages a projection 129a on the lever 129 and prevents relative movement between this lever and the lug I30. Consequently the cam 'l2l lifts the lug 130 and through the action of lever I29 and finger 123 pulls'the rod H3 downwards thereby bringing the register wheels M5 into engagement with the actuator racks.

The inclined portion 12!!) of cam "I is so placed that it pulls the rod 1 l9 downwardly before the cam M5 has released the bail 109 to permit the actuators to descend and while the stepped plates associated with these actuators are in their normal positions to the left.

During th;s operation these accumulator plates 60! and 502 and so on are held in their normal positions by the latch 202 which is released by actuation of the keys during multiplying operations but not by the clearance key 435.

When the bail 103 is thus lowered the actuators descend and in so doing turn the register wheels backwards until the latter reach zero.

Any known form of register adapted for sterling calculations may be used. As will be well understood the backward rotation of the register wheels will be arrested by the usual form of transfer tooth engaging the usual form of transfer pawl when zero is reached.

It will be now understood why the additional deep slots 660a, Gila, 562a and so on are provided in the final result plates 150i, 603, 606 and 609 and so on. If these slots were not provided the projection 649a for example, on the one eighth of a penny actuator 649 would normally be located over the zero step of the steps 660 for the plate 6M and consequently the actuator 649 would be unable to descend in order to restore the corresponding register wheel to zero. Theprovision of the additional slot 550a in the plate 60! permits the descent of the coresponding actuator 649 for the purpose of restoring its corresponding register wheel to zero. The provision of this slot' 600a however, necessitates the plate 60l making one step movement even when the amount to be set up on this plate 501 is zero.

When a transfer of one unit has occurred from one denomination to the other as in the case of pence to shillings, or units of shillings to tens of shillings, the final product plate in the denomination to which the transfer has occurred will be one step in advance of the adjacent plate in the same denomination.

In order to permit restoration of the final product plates to their normal positions relatively to the adjacent plates before all the plates commence to return, the restoring bar is constructed in the following manner.

Mounted on the upper surface of the restoring bar 105 is a supplementary restoring bar 131 having slots 138 engaging pins 139 projecting from the main restoring bar 105 (Fig. 10). The length of the slots 138 is such that the supplementary restoring bar 131- can advance with respect to the restoring bar a distance equal to the width of one of the steps in the stepped plates. The supplementary restoring bar 131 carries a lug at each end on which is pivoted a latch 141 having a tail 142. When the supplementary restoring bar 131 is in its rearmost position its front edge is flush with the front edge of the main restoring bar 105 and the latches 141 are then resting on the tops of lugs 143 formed at each end of the bar 105. As the restoring bar 105 is moved rearwardly, that is to say to the right in Fig. 1 by means of the arms 101 and cam 108, the rear edge of the supplementary restoring bar 131 engages a cross-rod 144 (Fig. 1) carried between the side plates of the frame. This crossrod is disposed in such a position that it is engaged by the supplementary restoring bar when the main restoring bar 105 reaches a position which is one step in advance of its rearmost position. Consequently as the. restoring bar 105 travels still further rearwardly the supplementary bar 131 is held back so that the bar 105 moves rearwardly one step relatively to the bar 131 and the latches 14! drop off the lugs 143 and, by engaging over these lugs, retain the bar 131 one step in advance of the bar 105.

The stepped plates other than the final product plates are provided with notches 145 in their rear edges, that is to say, the plates 602, 804, 305, 601, 608, N0, 5| 1, Bit, H4 and the corresponding plates in higher denominations.

When the restoring bar returns to the left the bar 131 enters the notches 145 in the rear edges of the plates 602, 604 and so on which are projecting beyond the other plates after moving one step engages the rear edges of the other plates 602, 604 and so on. At this moment the bar 105 engages the rear edges of the plates MI, 1 603 and so on, so that the two bars 105, 131 return all the plates simultaneously.

Since the bar 131 is in front of the bar 105 the plates 802, 004, and so on will reach the end of their return movement one step in advance of the plates SM, 003 and so on and Just before the plates 602, 604 and so on reach the end of their travel the tails 142 of the latches 1 engage a cross bar 146 whereby the latches lift clear of the lugs 143. The further movement of the bar 105 completes the return of the plates 60!, 503 and so on, and during this movement the bar 105 moves relatively .to bar 131 which is held stationary by engagement with the rear edges of the plates 602, 604 and so on which are fully restored. The relative movement of bars 105 and 131 brings the lugs 143 once again below the latches 1.

It will be remembered that a transfer from the tens of shillings plate 809 to the units of 3 pounds plate 512 is effected by means of the arm 686, sleeve 681 and arm 692 controlling the vertical position of the slide 688 which through pin 693 and slot 693a controls the movement of plate 6i! relative to plate 6H which carries the 3 slide 680.

If the lug 685 has moved up on to one of the steps 551 to transfer one unit to the pounds, and if also the plate 609 were displaced to the right to a greater extent than the plate H2 it 4( would be impossible to return the plates since the restoring bar 105 would strike the plate 503 first and through the connection, 086, 501, 502, SM, 688, 693, 693a would push the plate M2 to the left in advance of plate 509. plate 6l2 reached its limiting position to the left the restoring bar would be unable to move any further since plate 500 would be held back by the engagement of lug 685 with the step 651.

In order to obviate this occurrence means is 5( provided for returning the arm 686 to its lowermost position before the plate 609 commences to move back to its normal position.

For this purpose a lever 141 (Fig. 9) is provided, which is secured to a shaft 148 rotatably 55 mounted on the side plates 6| 6, and having its end 149 resting on the top of the slide 680. Also secured to shaft 148 is a lever 150 pivoted to a vertical rod 15l sliding on guides attached to one side plate BIG and carrying at its lower end 0 a roller 152 resting on a cam 153 carried on a slide 154 pivoted to one of the arms 101 which operate the restoring bar 105. When the plate 612 is in its normal position to the left the roller 152 is at the right hand end 5 they are capable. The bar 105 then moves still .15!

Then when further to the right, whereupon the roller "2 rides down the inclined portion of the cam 153 and permits the slide 688 to rise to the position determined by the particular tooth 85'! with which the lug 685 engages.

On the return stroke of the restoring ltd the inclined part of cam 153 lifts the rod H53 and through the levers I48 and ill pushes the slide 688 downwards thereby returning the arm 686 to its lowermost position. At the same time the pin 693 acting on the cam slot Gnu returns the plate BIZ to its normal position relative to the plate 6| I, whereupon the restoring bars I05, '13! return both plates 6| l, 612 to their normal positions in the machine together with all the other plates.

If desired means may be provided for recording the products obtained by means of the mechanism according to the invention. For example the actuator racks 649 to 652 and so on may carry type or may serve to set punches to punch the product in a statistical record card or the like.

What I claim is:

1. Mechanism for accumulating the partial products obtained from the multiplication of two factors comprising in combination a frame, a plurality of accumulator plates pertaining to a single denomination of the product, said plates being slidably mounted in said frame, a settable stop for one of said plates, said stop being mounted in the frame, a settable stop for the adjacent plate, said second mentioned stop being carried on said first mentioned plate, means for setting said stops and means for maintaining the stop which is carried on said first mentioned plate in operative relation with the setting means irrespective of the position of the plate on which said stop is carried.

2. Mechanism for accumulating the partial products obtained from the multiplication of two factors in a machine including a series of denominational partial product elements compris ing in combination a frame, three accumulator plates pertaining to a single denomination of the product, a settable stop for the first of said plates, said stop being carried in the frame, a settable stop for the second of said plates, said second stop being carried by said first plate, a

settable stop for the third of said plates, said third stop being carried by said second plate, means for setting said stops under the control of the partial product elements, spring means for moving said plates up to their stops, means for maintaining the second and third stops in operative relation with the setting means irrespective of the position of the plate on which the stop is carried, a plurality of numerical abutments carried on the third plate, said abutments representing all possible digits of the product in the denomination to which said plate relates, a reading element mounted in the frame, spring means for moving said reading element until arrested by one of said numerical abutments, whereby said reading element receives a setting, a receiving Wheel, and means for transferring to said receiving Wheel the setting of said reading element.

'3. Mechanism according to claim 2 for accumulating partial products wherein the setting means for the third stop comprises an arm pivoted to said stop, a lower denominational accumulator plate, a second arm, a cam on said lower denominational plate disposed to rock said second arm when said plate moves beyond the highest digit in its denomination, and an operative connection between the two said arms whereby when said second arm is rocked, said first arm is also rocked and moves said third step.

4. Mechanism for accumulating the partial products of the multiplication of sterling amounts comprising a frame, and, in the units of pounds denomination a transfer plate for the reception of amounts transferred from the tens of shillings denomination, said transfer plate being slidably mounted in said frame, a settable stop for said transfer plate, a final product plate in the tens of shillings denomination, said final product plate being formed with steps each representing two units of movement of said plate, an arm pivoted to said settable stop, a second arm co-operating with the steps in said tens of shillings plate, an operative connection between said arms and means for returning said arms to their normal position before the tens of shillings plate is returned to its normal position.

' av'ii- -ST CHARLES McCLURE. 

